void compute_step_factor(int nelr, double* variables, double* areas, double* step_factors)
{
{ const unsigned long long parallel_for_start = current_time_ns();
#pragma omp parallel for default(shared) schedule(static)
for(int i = 0; i < nelr; i++)
{
double density = variables[NVAR*i + VAR_DENSITY];
cfd_double3 momentum;
momentum.x = variables[NVAR*i + (VAR_MOMENTUM+0)];
momentum.y = variables[NVAR*i + (VAR_MOMENTUM+1)];
momentum.z = variables[NVAR*i + (VAR_MOMENTUM+2)];
double density_energy = variables[NVAR*i + VAR_DENSITY_ENERGY];
cfd_double3 velocity; compute_velocity(density, momentum, velocity);
double speed_sqd = compute_speed_sqd(velocity);
double pressure = compute_pressure(density, density_energy, speed_sqd);
double speed_of_sound = compute_speed_of_sound(density, pressure);
// dt = double(0.5) * std::sqrt(areas[i]) / (||v|| + c).... but when we do time stepping, this later would need to be divided by the area, so we just do it all at once
step_factors[i] = double(0.5) / (std::sqrt(areas[i]) * (std::sqrt(speed_sqd) + speed_of_sound));
} ;
const unsigned long long parallel_for_end = current_time_ns();
printf("pragma155_omp_parallel %llu ns\n", parallel_for_end - parallel_for_start); }
}
void compute_flux_contributions(int nelr, double* variables, double* fc_momentum_x, double* fc_momentum_y, double* fc_momentum_z, double* fc_density_energy)
{
#pragma acc kernels
for(int i = 0; i < nelr; i++)
{
double density_i = variables[NVAR*i + VAR_DENSITY];
double3 momentum_i;
momentum_i.x = variables[NVAR*i + (VAR_MOMENTUM+0)];
momentum_i.y = variables[NVAR*i + (VAR_MOMENTUM+1)];
momentum_i.z = variables[NVAR*i + (VAR_MOMENTUM+2)];
double density_energy_i = variables[NVAR*i + VAR_DENSITY_ENERGY];
double3 velocity_i; compute_velocity(density_i, momentum_i, velocity_i);
double speed_sqd_i = compute_speed_sqd(velocity_i);
double speed_i = sqrtf(speed_sqd_i);
double pressure_i = compute_pressure(density_i, density_energy_i, speed_sqd_i);
double speed_of_sound_i = compute_speed_of_sound(density_i, pressure_i);
double3 fc_i_momentum_x, fc_i_momentum_y, fc_i_momentum_z;
double3 fc_i_density_energy;
compute_flux_contribution(density_i, momentum_i, density_energy_i, pressure_i, velocity_i, fc_i_momentum_x, fc_i_momentum_y, fc_i_momentum_z, fc_i_density_energy);
fc_momentum_x[i*NDIM + 0] = fc_i_momentum_x.x;
fc_momentum_x[i*NDIM + 1] = fc_i_momentum_x.y;
fc_momentum_x[i*NDIM+ 2] = fc_i_momentum_x.z;
fc_momentum_y[i*NDIM+ 0] = fc_i_momentum_y.x;
fc_momentum_y[i*NDIM+ 1] = fc_i_momentum_y.y;
fc_momentum_y[i*NDIM+ 2] = fc_i_momentum_y.z;
fc_momentum_z[i*NDIM+ 0] = fc_i_momentum_z.x;
fc_momentum_z[i*NDIM+ 1] = fc_i_momentum_z.y;
fc_momentum_z[i*NDIM+ 2] = fc_i_momentum_z.z;
fc_density_energy[i*NDIM+ 0] = fc_i_density_energy.x;
fc_density_energy[i*NDIM+ 1] = fc_i_density_energy.y;
fc_density_energy[i*NDIM+ 2] = fc_i_density_energy.z;
}
}
void compute_step_factor(int nelr, double* variables, double* areas, double* step_factors)
{
#pragma acc kernels
for(int i = 0; i < nelr; i++)
{
double density = variables[NVAR*i + VAR_DENSITY];
double3 momentum;
momentum.x = variables[NVAR*i + (VAR_MOMENTUM+0)];
momentum.y = variables[NVAR*i + (VAR_MOMENTUM+1)];
momentum.z = variables[NVAR*i + (VAR_MOMENTUM+2)];
double density_energy = variables[NVAR*i + VAR_DENSITY_ENERGY];
double3 velocity; compute_velocity(density, momentum, velocity);
double speed_sqd = compute_speed_sqd(velocity);
double pressure = compute_pressure(density, density_energy, speed_sqd);
double speed_of_sound = compute_speed_of_sound(density, pressure);
// dt = double(0.5) * std::sqrt(areas[i]) / (||v|| + c).... but when we do time stepping, this later would need to be divided by the area, so we just do it all at once
step_factors[i] = double(0.5) / (std::sqrt(areas[i]) * (std::sqrt(speed_sqd) + speed_of_sound));
}
}
void compute_flux(int nelr, int* elements_surrounding_elements, double* normals, double* variables, double* fluxes)
{
double smoothing_coefficient = double(0.2f);
{ const unsigned long long parallel_for_start = current_time_ns();
#pragma omp parallel for default(shared) schedule(static)
for(int i = 0; i < nelr; i++)
{
int j, nb;
cfd_double3 normal; double normal_len;
double factor;
double density_i = variables[NVAR*i + VAR_DENSITY];
cfd_double3 momentum_i;
momentum_i.x = variables[NVAR*i + (VAR_MOMENTUM+0)];
momentum_i.y = variables[NVAR*i + (VAR_MOMENTUM+1)];
momentum_i.z = variables[NVAR*i + (VAR_MOMENTUM+2)];
double density_energy_i = variables[NVAR*i + VAR_DENSITY_ENERGY];
cfd_double3 velocity_i; compute_velocity(density_i, momentum_i, velocity_i);
double speed_sqd_i = compute_speed_sqd(velocity_i);
double speed_i = std::sqrt(speed_sqd_i);
double pressure_i = compute_pressure(density_i, density_energy_i, speed_sqd_i);
double speed_of_sound_i = compute_speed_of_sound(density_i, pressure_i);
cfd_double3 flux_contribution_i_momentum_x, flux_contribution_i_momentum_y, flux_contribution_i_momentum_z;
cfd_double3 flux_contribution_i_density_energy;
compute_flux_contribution(density_i, momentum_i, density_energy_i, pressure_i, velocity_i, flux_contribution_i_momentum_x, flux_contribution_i_momentum_y, flux_contribution_i_momentum_z, flux_contribution_i_density_energy);
double flux_i_density = double(0.0);
cfd_double3 flux_i_momentum;
flux_i_momentum.x = double(0.0);
flux_i_momentum.y = double(0.0);
flux_i_momentum.z = double(0.0);
double flux_i_density_energy = double(0.0);
cfd_double3 velocity_nb;
double density_nb, density_energy_nb;
cfd_double3 momentum_nb;
cfd_double3 flux_contribution_nb_momentum_x, flux_contribution_nb_momentum_y, flux_contribution_nb_momentum_z;
cfd_double3 flux_contribution_nb_density_energy;
double speed_sqd_nb, speed_of_sound_nb, pressure_nb;
for(j = 0; j < NNB; j++)
{
nb = elements_surrounding_elements[i*NNB + j];
normal.x = normals[(i*NNB + j)*NDIM + 0];
normal.y = normals[(i*NNB + j)*NDIM + 1];
normal.z = normals[(i*NNB + j)*NDIM + 2];
normal_len = std::sqrt(normal.x*normal.x + normal.y*normal.y + normal.z*normal.z);
if(nb >= 0) // a legitimate neighbor
{
density_nb = variables[nb*NVAR + VAR_DENSITY];
momentum_nb.x = variables[nb*NVAR + (VAR_MOMENTUM+0)];
momentum_nb.y = variables[nb*NVAR + (VAR_MOMENTUM+1)];
momentum_nb.z = variables[nb*NVAR + (VAR_MOMENTUM+2)];
density_energy_nb = variables[nb*NVAR + VAR_DENSITY_ENERGY];
compute_velocity(density_nb, momentum_nb, velocity_nb);
speed_sqd_nb = compute_speed_sqd(velocity_nb);
pressure_nb = compute_pressure(density_nb, density_energy_nb, speed_sqd_nb);
speed_of_sound_nb = compute_speed_of_sound(density_nb, pressure_nb);
compute_flux_contribution(density_nb, momentum_nb, density_energy_nb, pressure_nb, velocity_nb, flux_contribution_nb_momentum_x, flux_contribution_nb_momentum_y, flux_contribution_nb_momentum_z, flux_contribution_nb_density_energy);
// artificial viscosity
factor = -normal_len*smoothing_coefficient*double(0.5)*(speed_i + std::sqrt(speed_sqd_nb) + speed_of_sound_i + speed_of_sound_nb);
flux_i_density += factor*(density_i-density_nb);
flux_i_density_energy += factor*(density_energy_i-density_energy_nb);
flux_i_momentum.x += factor*(momentum_i.x-momentum_nb.x);
flux_i_momentum.y += factor*(momentum_i.y-momentum_nb.y);
flux_i_momentum.z += factor*(momentum_i.z-momentum_nb.z);
// accumulate cell-centered fluxes
factor = double(0.5)*normal.x;
flux_i_density += factor*(momentum_nb.x+momentum_i.x);
flux_i_density_energy += factor*(flux_contribution_nb_density_energy.x+flux_contribution_i_density_energy.x);
flux_i_momentum.x += factor*(flux_contribution_nb_momentum_x.x+flux_contribution_i_momentum_x.x);
flux_i_momentum.y += factor*(flux_contribution_nb_momentum_y.x+flux_contribution_i_momentum_y.x);
flux_i_momentum.z += factor*(flux_contribution_nb_momentum_z.x+flux_contribution_i_momentum_z.x);
factor = double(0.5)*normal.y;
flux_i_density += factor*(momentum_nb.y+momentum_i.y);
flux_i_density_energy += factor*(flux_contribution_nb_density_energy.y+flux_contribution_i_density_energy.y);
flux_i_momentum.x += factor*(flux_contribution_nb_momentum_x.y+flux_contribution_i_momentum_x.y);
flux_i_momentum.y += factor*(flux_contribution_nb_momentum_y.y+flux_contribution_i_momentum_y.y);
flux_i_momentum.z += factor*(flux_contribution_nb_momentum_z.y+flux_contribution_i_momentum_z.y);
factor = double(0.5)*normal.z;
flux_i_density += factor*(momentum_nb.z+momentum_i.z);
flux_i_density_energy += factor*(flux_contribution_nb_density_energy.z+flux_contribution_i_density_energy.z);
flux_i_momentum.x += factor*(flux_contribution_nb_momentum_x.z+flux_contribution_i_momentum_x.z);
flux_i_momentum.y += factor*(flux_contribution_nb_momentum_y.z+flux_contribution_i_momentum_y.z);
flux_i_momentum.z += factor*(flux_contribution_nb_momentum_z.z+flux_contribution_i_momentum_z.z);
}
else if(nb == -1) // a wing boundary
{
flux_i_momentum.x += normal.x*pressure_i;
flux_i_momentum.y += normal.y*pressure_i;
flux_i_momentum.z += normal.z*pressure_i;
}
else if(nb == -2) // a far field boundary
{
factor = double(0.5)*normal.x;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+0]+momentum_i.x);
flux_i_density_energy += factor*(ff_flux_contribution_density_energy.x+flux_contribution_i_density_energy.x);
flux_i_momentum.x += factor*(ff_flux_contribution_momentum_x.x + flux_contribution_i_momentum_x.x);
flux_i_momentum.y += factor*(ff_flux_contribution_momentum_y.x + flux_contribution_i_momentum_y.x);
flux_i_momentum.z += factor*(ff_flux_contribution_momentum_z.x + flux_contribution_i_momentum_z.x);
factor = double(0.5)*normal.y;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+1]+momentum_i.y);
flux_i_density_energy += factor*(ff_flux_contribution_density_energy.y+flux_contribution_i_density_energy.y);
flux_i_momentum.x += factor*(ff_flux_contribution_momentum_x.y + flux_contribution_i_momentum_x.y);
flux_i_momentum.y += factor*(ff_flux_contribution_momentum_y.y + flux_contribution_i_momentum_y.y);
flux_i_momentum.z += factor*(ff_flux_contribution_momentum_z.y + flux_contribution_i_momentum_z.y);
factor = double(0.5)*normal.z;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+2]+momentum_i.z);
flux_i_density_energy += factor*(ff_flux_contribution_density_energy.z+flux_contribution_i_density_energy.z);
flux_i_momentum.x += factor*(ff_flux_contribution_momentum_x.z + flux_contribution_i_momentum_x.z);
flux_i_momentum.y += factor*(ff_flux_contribution_momentum_y.z + flux_contribution_i_momentum_y.z);
flux_i_momentum.z += factor*(ff_flux_contribution_momentum_z.z + flux_contribution_i_momentum_z.z);
}
}
fluxes[i*NVAR + VAR_DENSITY] = flux_i_density;
fluxes[i*NVAR + (VAR_MOMENTUM+0)] = flux_i_momentum.x;
fluxes[i*NVAR + (VAR_MOMENTUM+1)] = flux_i_momentum.y;
fluxes[i*NVAR + (VAR_MOMENTUM+2)] = flux_i_momentum.z;
fluxes[i*NVAR + VAR_DENSITY_ENERGY] = flux_i_density_energy;
} ;
const unsigned long long parallel_for_end = current_time_ns();
printf("pragma186_omp_parallel %llu ns\n", parallel_for_end - parallel_for_start); }
}
/*Algoritmo Principal*/
int main(int argc, char *argv[])
{
char name[20];// = "_kita_1";
char archiveName[20] = "archive";
char fitputName[20] = "fitput";
char varputName[20] = "varput";
char hvName[20]= "hv";
unsigned int i, j, t;
unsigned int fun, gen;
clock_t startTime, endTime;
double duration, clocktime;
FILE *fitfile,*varfile;
/*Parametros iniciales*/
strcpy(name,argv[1]);
fun = atoi(argv[2]);
gen = atoi(argv[3]);
printf("%s %d %d \n",name,fun,gen);
initialize_data(fun,gen);
/*Iniciar variables*/
initialize_memory();
/*
sprintf(name,"kita_1_");
sprintf(archiveName,strcat(name,"archive.out"));
sprintf(fitputName, strcat(name,"fitput.out"));
sprintf(varputName, strcat(name,"varput.out"));
sprintf(hvName,strcat(name,"hv.out"));
*/
//fitfile = fopen(strcat(strcat(fitputName,name),".out"),"w");
//varfile = fopen(strcat(strcat(varputName,name),".out"),"w");
//hv = fopen(strcat(strcat(hvName,name),".out"),"w");
/* Iniciar generador de aleatorios*/
initialize_rand();
startTime = clock();
/* Iniciar contador de generaciones*/
t = 0;
/* Iniciar valores de la poblacion de manera aleatoria*/
initialize_pop();
/* Calcular velocidad inicial*/
initialize_vel();
/* Evaluar las particulas de la poblacion*/
evaluate();
/* Almacenar el pBest inicial (variables and valor de aptitud) de las particulas*/
store_pbests();
/* Insertar las particulas no domindas de la poblacion en el archivo*/
insert_nondom();
//printf("\n%d",nondomCtr);
/*Ciclo Principal*/
while(t <= maxgen)
{
//clocktime = (clock() - startTime)/(double)CLOCKS_PER_SEC;
/*if(verbose > 0 && t%printevery==0 || t == maxgen)
{
fprintf(stdout,"Generation %d Time: %.2f sec\n",t,clocktime);
fflush(stdout);
}*/
/*if(t%printevery==0 || t == maxgen)
{
fprintf(outfile,"Generation %d Time: %.2f sec\n",t,clocktime);
}*/
/* Calcular la nueva velocidad de cada particula en la pooblacion*/
//printf("\n 1");
compute_velocity();
/* Calcular la nueva posicion de cada particula en la poblacion*/
//printf("\n 2");
compute_position();
/* Mantener las particulas en la poblacion de la poblacion en el espacio de busqueda*/
//printf("\n 3");
maintain_particles();
/* Pertubar las particulas en la poblacion*/
if(t < maxgen * pMut)
mutate(t);
/* Evaluar las particulas en la poblacion*/
//printf("\n 4");
evaluate();
/* Insertar nuevas particulas no domindas en el archivo*/
//printf("\n 5");
update_archive();
/* Actualizar el pBest de las particulas en la poblacion*/
//printf("\n 6");
update_pbests();
/* Escribir resultados del mejor hasta ahora*/
//verbose > 0 && t%printevery==0 || t == maxgen
/*if(t%printevery==0 || t == maxgen)
{
//fprintf(outfile, "Size of Pareto Set: %d\n", nondomCtr);
fprintf(fitfile, "%d\n",t);
fprintf(varfile, "%d\n",t);
for(i = 0; i < nondomCtr; i++)
{
for(j = 0; j < maxfun; j++)
fprintf(fitfile, "%f ", archiveFit[i][j]);
fprintf(fitfile, "\n");
}
fprintf(fitfile, "\n\n");
fflush(fitfile);
for(i = 0; i < nondomCtr; i++)
{
for(j = 0; j < maxfun; j++)
fprintf(varfile, "%f ", archiveVar[i][j]);
fprintf(varfile, "\n");
}
fprintf(varfile, "\n\n");
fflush(varfile);
}*/
/* Incrementar contador de generaciones*/
t++;
//printf("%d\n",t);
}
/* Escribir resultados en el archivo */
save_results(strcat(strcat(archiveName,name),".out"));
endTime = clock();
duration = ( endTime - startTime ) / (double)CLOCKS_PER_SEC;
fprintf(stdout, "%lf sec\n", duration);
//fclose(fitfile);
//fclose(varfile);
free_memory();
return EXIT_SUCCESS;
}
void compute_flux(int nelr, int* elements_surrounding_elements, double* normals, double* variables, double* fc_momentum_x, double* fc_momentum_y, double* fc_momentum_z, double* fc_density_energy, double* fluxes)
{
const double smoothing_coefficient = double(0.2);
#pragma acc kernels
for(int i = 0; i < nelr; i++)
{
int j, nb;
double3 normal; double normal_len;
double factor;
double density_i = variables[NVAR*i + VAR_DENSITY];
double3 momentum_i;
momentum_i.x = variables[NVAR*i + (VAR_MOMENTUM+0)];
momentum_i.y = variables[NVAR*i + (VAR_MOMENTUM+1)];
momentum_i.z = variables[NVAR*i + (VAR_MOMENTUM+2)];
double density_energy_i = variables[NVAR*i + VAR_DENSITY_ENERGY];
double3 velocity_i; compute_velocity(density_i, momentum_i, velocity_i);
double speed_sqd_i = compute_speed_sqd(velocity_i);
double speed_i = std::sqrt(speed_sqd_i);
double pressure_i = compute_pressure(density_i, density_energy_i, speed_sqd_i);
double speed_of_sound_i = compute_speed_of_sound(density_i, pressure_i);
double3 fc_i_momentum_x, fc_i_momentum_y, fc_i_momentum_z;
double3 fc_i_density_energy;
fc_i_momentum_x.x = fc_momentum_x[i*NDIM + 0];
fc_i_momentum_x.y = fc_momentum_x[i*NDIM + 1];
fc_i_momentum_x.z = fc_momentum_x[i*NDIM + 2];
fc_i_momentum_y.x = fc_momentum_y[i*NDIM + 0];
fc_i_momentum_y.y = fc_momentum_y[i*NDIM + 1];
fc_i_momentum_y.z = fc_momentum_y[i*NDIM + 2];
fc_i_momentum_z.x = fc_momentum_z[i*NDIM + 0];
fc_i_momentum_z.y = fc_momentum_z[i*NDIM + 1];
fc_i_momentum_z.z = fc_momentum_z[i*NDIM + 2];
fc_i_density_energy.x = fc_density_energy[i*NDIM + 0];
fc_i_density_energy.y = fc_density_energy[i*NDIM + 1];
fc_i_density_energy.z = fc_density_energy[i*NDIM + 2];
double flux_i_density = double(0.0);
double3 flux_i_momentum;
flux_i_momentum.x = double(0.0);
flux_i_momentum.y = double(0.0);
flux_i_momentum.z = double(0.0);
double flux_i_density_energy = double(0.0);
double3 velocity_nb;
double density_nb, density_energy_nb;
double3 momentum_nb;
double3 fc_nb_momentum_x, fc_nb_momentum_y, fc_nb_momentum_z;
double3 fc_nb_density_energy;
double speed_sqd_nb, speed_of_sound_nb, pressure_nb;
for(j = 0; j < NNB; j++)
{
nb = elements_surrounding_elements[i*NNB + j];
normal.x = normals[(i*NNB + j)*NDIM + 0];
normal.y = normals[(i*NNB + j)*NDIM + 1];
normal.z = normals[(i*NNB + j)*NDIM + 2];
normal_len = std::sqrt(normal.x*normal.x + normal.y*normal.y + normal.z*normal.z);
if(nb >= 0) // a legitimate neighbor
{
density_nb = variables[nb*NVAR + VAR_DENSITY];
momentum_nb.x = variables[nb*NVAR + (VAR_MOMENTUM+0)];
momentum_nb.y = variables[nb*NVAR + (VAR_MOMENTUM+1)];
momentum_nb.z = variables[nb*NVAR + (VAR_MOMENTUM+2)];
density_energy_nb = variables[nb*NVAR + VAR_DENSITY_ENERGY];
compute_velocity(density_nb, momentum_nb, velocity_nb);
speed_sqd_nb = compute_speed_sqd(velocity_nb);
pressure_nb = compute_pressure(density_nb, density_energy_nb, speed_sqd_nb);
speed_of_sound_nb = compute_speed_of_sound(density_nb, pressure_nb);
fc_nb_momentum_x.x = fc_momentum_x[nb*NDIM + 0];
fc_nb_momentum_x.y = fc_momentum_x[nb*NDIM + 1];
fc_nb_momentum_x.z = fc_momentum_x[nb*NDIM + 2];
fc_nb_momentum_y.x = fc_momentum_y[nb*NDIM + 0];
fc_nb_momentum_y.y = fc_momentum_y[nb*NDIM + 1];
fc_nb_momentum_y.z = fc_momentum_y[nb*NDIM + 2];
fc_nb_momentum_z.x = fc_momentum_z[nb*NDIM + 0];
fc_nb_momentum_z.y = fc_momentum_z[nb*NDIM + 1];
fc_nb_momentum_z.z = fc_momentum_z[nb*NDIM + 2];
fc_nb_density_energy.x = fc_density_energy[nb*NDIM + 0];
fc_nb_density_energy.y = fc_density_energy[nb*NDIM + 1];
// artificial viscosity
factor = -normal_len*smoothing_coefficient*double(0.5)*(speed_i + std::sqrt(speed_sqd_nb) + speed_of_sound_i + speed_of_sound_nb);
flux_i_density += factor*(density_i-density_nb);
flux_i_density_energy += factor*(density_energy_i-density_energy_nb);
flux_i_momentum.x += factor*(momentum_i.x-momentum_nb.x);
flux_i_momentum.y += factor*(momentum_i.y-momentum_nb.y);
flux_i_momentum.z += factor*(momentum_i.z-momentum_nb.z);
// accumulate cell-centered fluxes
factor = double(0.5)*normal.x;
flux_i_density += factor*(momentum_nb.x+momentum_i.x);
flux_i_density_energy += factor*(fc_nb_density_energy.x+fc_i_density_energy.x);
flux_i_momentum.x += factor*(fc_nb_momentum_x.x+fc_i_momentum_x.x);
flux_i_momentum.y += factor*(fc_nb_momentum_y.x+fc_i_momentum_y.x);
flux_i_momentum.z += factor*(fc_nb_momentum_z.x+fc_i_momentum_z.x);
factor = double(0.5)*normal.y;
flux_i_density += factor*(momentum_nb.y+momentum_i.y);
flux_i_density_energy += factor*(fc_nb_density_energy.y+fc_i_density_energy.y);
flux_i_momentum.x += factor*(fc_nb_momentum_x.y+fc_i_momentum_x.y);
flux_i_momentum.y += factor*(fc_nb_momentum_y.y+fc_i_momentum_y.y);
flux_i_momentum.z += factor*(fc_nb_momentum_z.y+fc_i_momentum_z.y);
factor = double(0.5)*normal.z;
flux_i_density += factor*(momentum_nb.z+momentum_i.z);
flux_i_density_energy += factor*(fc_nb_density_energy.z+fc_i_density_energy.z);
flux_i_momentum.x += factor*(fc_nb_momentum_x.z+fc_i_momentum_x.z);
flux_i_momentum.y += factor*(fc_nb_momentum_y.z+fc_i_momentum_y.z);
flux_i_momentum.z += factor*(fc_nb_momentum_z.z+fc_i_momentum_z.z);
}
else if(nb == -1) // a wing boundary
{
flux_i_momentum.x += normal.x*pressure_i;
flux_i_momentum.y += normal.y*pressure_i;
flux_i_momentum.z += normal.z*pressure_i;
}
else if(nb == -2) // a far field boundary
{
factor = double(0.5)*normal.x;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+0]+momentum_i.x);
flux_i_density_energy += factor*(ff_fc_density_energy.x+fc_i_density_energy.x);
flux_i_momentum.x += factor*(ff_fc_momentum_x.x + fc_i_momentum_x.x);
flux_i_momentum.y += factor*(ff_fc_momentum_y.x + fc_i_momentum_y.x);
flux_i_momentum.z += factor*(ff_fc_momentum_z.x + fc_i_momentum_z.x);
factor = double(0.5)*normal.y;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+1]+momentum_i.y);
flux_i_density_energy += factor*(ff_fc_density_energy.y+fc_i_density_energy.y);
flux_i_momentum.x += factor*(ff_fc_momentum_x.y + fc_i_momentum_x.y);
flux_i_momentum.y += factor*(ff_fc_momentum_y.y + fc_i_momentum_y.y);
flux_i_momentum.z += factor*(ff_fc_momentum_z.y + fc_i_momentum_z.y);
factor = double(0.5)*normal.z;
flux_i_density += factor*(ff_variable[VAR_MOMENTUM+2]+momentum_i.z);
flux_i_density_energy += factor*(ff_fc_density_energy.z+fc_i_density_energy.z);
flux_i_momentum.x += factor*(ff_fc_momentum_x.z + fc_i_momentum_x.z);
flux_i_momentum.y += factor*(ff_fc_momentum_y.z + fc_i_momentum_y.z);
flux_i_momentum.z += factor*(ff_fc_momentum_z.z + fc_i_momentum_z.z);
}
}
fluxes[i*NVAR + VAR_DENSITY] = flux_i_density;
fluxes[i*NVAR + (VAR_MOMENTUM+0)] = flux_i_momentum.x;
fluxes[i*NVAR + (VAR_MOMENTUM+1)] = flux_i_momentum.y;
fluxes[i*NVAR + (VAR_MOMENTUM+2)] = flux_i_momentum.z;
fluxes[i*NVAR + VAR_DENSITY_ENERGY] = flux_i_density_energy;
}
}
